Method of Cooling axle

ABSTRACT

A work vehicle includes a frame and an axle assembly coupled to the frame. The axle assembly includes a first axle shaft and a first axle housing, with the first axle shaft disposed substantially within the first axle housing; a first wheel coupled to the first axle assembly; an axle lubricating fluid disposed within the first axle housing; and a first axle cooling device disposed within the first axle housing, in contact with at least a portion of the lubricating fluid, and including a first coil. Also disclosed is a method of cooling an axle assembly of a work vehicle. The method includes steps of removing heat from the lubricating fluid by placing the lubricating fluid in contact with the outer surface of a coil, and removing the heat from the inner surface of the coil by circulating the cooling fluid through the passage.

FIELD OF THE INVENTION

[0001] The present invention relates generally to the field of workvehicles. It relates more particularly to removal of braking heat froman axle of a wheeled loader.

BACKGROUND OF THE INVENTION

[0002] Some work vehicles, such as end loaders, must change theirdirections of movement frequently. To do this, wheel or live axle brakesare generally used to first bring the vehicle to a stop. When this isdone frequently, the brakes become overheated.

[0003] This has sometimes been resolved by placing the brakes inside anaxle housing, where the heat generated by brake friction is removed fromthe brake by an axle lubricating bath. The lubricant spreads the heatover the entire interior surface of the axle housing, whereupon thermalconduction through the walls of the axle housing heat the exteriorsurface of the axle housing and provide increased surface area for heatto be convected away by ambient air.

[0004] In some instances, however, convection to and from the axlehousing surfaces is insufficient to remove braking heat rapidly enough,and the axle lubricant consequently becomes excessively hot (e.g., above300 degrees Fahrenheit). This is injurious not only to the lubricantitself (accelerating oxidation and breakdown), but also to the bearingsand seals associated with the axle shaft.

[0005] Typically, the brake is a wet multiple disk brake; “wet”, becausethe disks rotate through a bath of lubricating oil. As the multiplebrake disks rotate through the lubricating oil, braking heat istransferred from the disks to the lubricating oil.

[0006] The temperature of the lubricating oil consequently increases,and some of the heat within the lubricating oil is transferred to theaxle shaft and to the axle housing. The axle shaft and axle housing areof limited size and mass and, hence, of limited heat capacity.Therefore, their temperatures begin to approach (under the duty cycle offrequent stops characteristic of a loader) the temperature of thelubricating oil because ambient air typically does not convect heat fromthe axle housing as rapidly as the brake convects heat into thelubricating oil. It is therefore necessary to actively cool thelubricating oil.

[0007] While one can add a cooling loop to an axle assembly and pump hotlubricating oil through a fan-cooled radiator, this is a costly andcumbersome approach. Further, it increases the number of opportunitiesfor leakage or contamination of the lubricating oil in what is typicallya dirty and dusty environment.

[0008] It would be advantageous to provide an apparatus and method ofremoving excessive heat from the axle lubricant, thereby cooling theaxle assembly, without substantially increasing the risks of lubricantleakage and/or contamination.

SUMMARY OF THE INVENTION

[0009] One embodiment of the invention relates to a work vehicleincluding a frame and an axle assembly coupled to the frame. The axleassembly includes an axle shaft and an axle housing. The axle shaft isdisposed substantially within the axle housing, and a wheel is coupledto the axle assembly. An axle lubricating fluid is disposed within theaxle housing. An axle cooling device is also disposed within the axlehousing, in contact with at least a portion of the lubricating fluid,and is configured as a coil including a plurality of elongate tubes.

[0010] Another embodiment of the invention relates to an axle assemblyfor a work vehicle. The axle assembly includes a first axle shaft and afirst axle housing, and a second axle shaft and a second axle housing.The first and second axle shafts are disposed substantially within thefirst axle housing and the second axle housing, respectively. The secondaxle shaft and the second axle housing are disposed coaxial with, and inopposing relationship to, the first axle shaft and the first axlehousing, respectively. This embodiment further includes a first coolingdevice disposed within the first axle housing, and a second coolingdevice disposed within the second axle housing. It further includes adifferential gearset housing positioned intermediate the first andsecond axle housings and defining a chamber configured to receive adifferential gearset. A differential gearset may also be included, andis disposed within the chamber and is rotatively coupled to the firstand second axle shafts. Further included are a lubricating fluiddisposed within the first and second axle housings. Still furtherincluded are a first axle cooling device including a first plurality ofelongate tubes and disposed within the first axle housing, and a secondaxle cooling device including a second plurality of elongate tubes anddisposed within the second axle housing.

[0011] Another embodiment of the invention relates to a method ofcooling an axle assembly of a work vehicle. The axle assembly includesan axle shaft, an axle housing configured to substantially surround theaxle shaft, a cooling coil housed within the axle housing and having apassage therethrough and outer and inner surfaces, a lubricating fluiddisposed within the axle housing, and a cooling fluid disposed withinthe passage. The lubricating fluid is of a higher temperature than isthe outer surface of the coil, and the outer surface of the coil is of ahigher temperature than is the cooling fluid. The method includes a stepof removing heat from the lubricating fluid by placing the lubricatingfluid in contact with the outer surface of the coil. The method alsoincludes a step of removing the heat from the inner surface of the coilby circulating the cooling fluid through the passage.

BRIEF DESCRIPTION OF THE DRAWINGS

[0012]FIG. 1 is a rear sectional elevation of an axle assembly;

[0013]FIG. 2 is a schematic diagram of an embodiment of an axle coolingapparatus for cooling a single axle assembly;

[0014]FIG. 3 is a schematic diagram of an embodiment of an axle coolingapparatus for cooling two axle assemblies; and

[0015]FIG. 4 is a schematic diagram of an alternative embodiment of anaxle cooling apparatus for cooling two axle assemblies.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0016]FIG. 1 shows a work vehicle 10 provided with a frame 12, an axleassembly 14, wheels 16, and an axle cooling apparatus 18. Frame 12 maybe of any of the conventional types including fabricated steel or castiron. Axle assembly 14 and axle cooling apparatus 18 are describedbelow, and wheel 16 may be of any of the conventional types; e.g.,rubber-tired, cleated, or tracked. Wheels 16 support axle assembly 14with respect to a pavement or ground surface 20, and axle assembly 14supports frame 12. Only one axle assembly 14 is shown, but work vehicle10 may include any number of axle assemblies 14.

[0017] Axle assembly 14 includes at least one axle shaft 22 generallycontained within an axle housing 24 and supported by axle housing 24 forrotative movement relative to axle housing 24. Axle shaft 22 is ofconventional construction, typically machined of a medium-carbon steeland hardened at least in the regions of splines (not shown). Axlehousing 24 is also generally of conventional construction (e.g., castgray or ductile iron or fabricated of steel), but is of generally largetransverse sectional size to accommodate a brake 26 and a coolingdevice, or coil 28 (both described below), as well as a planetarygearset (not shown). Axle housing 24 may be of any transverse sectionalshape; e.g., round, square, etc.

[0018] Brake 26, shown schematically in FIG. 1 as a single disk brakedby a caliper, is, in an exemplary embodiment, a wet multidisk brake ofwell-known and conventional design. The term “wet” refers to a bath oflubricating fluid 30 that at least partially immerses brake 26,lubricating fluid 30 thereby providing both lubrication and cooling ofbrake 26.

[0019] A cooling device, shown as a coil 28 and a portion of coolingsystem 18 (described below), is also housed within axle housing 24. Coil28 is a tubular device having a passage 32 provided internallytherethrough, is of generally conventional construction and isfabricated of a plurality of metal tubes 34, generally similar to a tubebundle of a shell-and-tube heat exchanger. In an exemplary embodiment,coil 28 is formed of a single length of tubing in one or more parallel“passes” by a series of 180 degree bends, providing a plurality ofparallel tube lengths, each length connected to an adjacent length atone end so that the passes are disposed in series flow arrangement andcoil 28 has one inlet 36 and one outlet 38. In an alternative embodiment(not shown), a coil is fabricated of a plurality of cut tube lengthsjoined to each other by “U”-shaped return bend fittings, themselvesfabricated, if necessary, of a street elbow secured and sealed to aconventional elbow. In a further alternative embodiment, coil 28includes fins, dimples, or is flattened to increase the surface areathereof in contact with lubricating fluid 30, and thereby to increasethe heat transfer from lubricating fluid 30 to coil 28.

[0020] Coil 28 is disposed near an inner bottom surface of axle housing24 to ensure its immersion in lubricating oil in various pitch and rollangles of work vehicle 10. In an exemplary embodiment, at least thelower portion of axle housing 24 is of a square transverse sectionalshape so that coil 28 may be formed of a flat sectional shape. In analternative embodiment, the transverse sectional shape of an axlehousing is generally circular and the sectional shape of a coil is thatof a segment of a circle having a slightly smaller radius than that ofan inner surface of the axle housing.

[0021] Passage 32 within coil 28 is filled with a cooling fluid 40(described below). If cooling fluid 40 is of a high pressure (e.g.,greater than 80 pounds per square inch), coil 28 is preferably fashionedof a formable steel tube material and secured to fittings by welding orbrazing. If cooling fluid 40 is of a lower pressure, coil 28 mayadvantageously be fashioned of a copper alloy (e.g., a soft brass) or analuminum alloy for higher thermal conductivity and therefore a higherrate of heat transfer.

[0022] Cooling fluid 40 may be any fluid, liquid or gaseous, withsufficient heat capacity and flow rate to remove braking heat from coil28. Since, however, most examples of work vehicle 10, such as a loader,are provided with hydraulic systems which include a hydraulic fluidgenerally maintained much lower than 300 degrees in temperature andotherwise suitable for removing heat from coil 28, in an exemplaryembodiment work vehicle 10 uses hydraulic fluid obtained from anexisting work vehicle hydraulic system as cooling fluid 40.

[0023] In operation, lubricating oil 30 receives heat from brake 26. Oil30 flows around coil 28. Coil 28 has outer and inner surfaces. Oil 30has a higher temperature than the outer surface of coil 28, and theouter surface of coil 28 has a higher temperature than cooling fluid 40.This causes heat transfer from lubricating oil 30 to cooling fluid 40.Heat is removed from cooling fluid 40 as described below with respect toone of FIGS. 2-4. FIG. 2 is a schematic diagram of an axle coolingcircuit 42 for an axle cooling apparatus 18 having one coil 28 forcooling of an axle assembly 14. Cooling apparatus 18 is a portion of amuch larger and more complex hydraulic power circuit (not shown)connected at a cooling apparatus outlet port 64 and a cooling apparatusinlet port 66 for driving actuators (not shown; e.g., power steering andbrakes, bucket and boom lift and tilt, etc.). Cooling apparatus 18includes coil 28, a pump 44 (in an exemplary embodiment, an existinghydraulic system pump of work vehicle 10) drawing hydraulic fluid, usedas cooling fluid 40, from an existing system reservoir 46; an existingheat exchanger 48, shown as an oil cooler; a control valve 50, shown asa back pressure regulating valve (BPRV), and appropriate fluid conduits52 (e.g., pipe, tube, hose).

[0024] Pump 44, reservoir 46, heat exchanger 48, and conduits 52 may befabricated from parts known to those of skill in the art. Coil 28 hasbeen described above. Control valve 50 is typically aspring-and-diaphragm or spring-and-piston apparatus having a pilot line54 in communication with the fluid whose pressure is to be controlled,fluid conducted by pilot line 54 applying pressure to the diaphragm orpiston in opposition to the force exerted by the spring, which isdisposed on an opposite side of the diaphragm or piston. A flowmodulating device (e.g., a valve plug or poppet) is rigidly secured tothe center of the diaphragm or the poppet, so that it moves in unisonwith the center of the diaphragm or the poppet in correspondence withthe pressure of the fluid and the spring rate of the spring. In anexemplary embodiment, control valve 50 is part number 4097 manufacturedby Shoemaker Inc., 12120 Yellow River Road, Fort Wayne, Ind. 46818 USA.

[0025] In an exemplary embodiment, heat exchanger 48 and coil 28 arefluidly disposed in parallel with control valve 50. In this way, a smallpressure drop (e.g., 50 pounds per square inch) may be imposed bycontrol valve 50 to direct cooling fluid 40 through heat exchanger 48and coil 28 without substantially decreasing the efficiency of the workvehicle hydraulic system.

[0026]FIG. 3 is a schematic diagram of a cooling circuit 42 a for usewith a cooling apparatus of a work vehicle, the work vehicle furthercomprising a second axle assembly, generally similar to first axleassembly 14 described above. The second axle assembly is disposedcoaxial with and in opposing relationship to the first axle assembly. Inthe embodiment shown in FIG. 1, the first axle assembly is the portionof axle 22 to the left of differential gearset 58, and the second axleassembly is the portion of axle 22 to the right of differential gearset58.

[0027] Cooling circuit 42 a includes a second coil 28 a, generallysimilar to first coil 28 described above. Second coil 28 a is fluidlydisposed in parallel flow relationship to first coil 28. Inlet port 36of first coil 28 is in fluid communication with inlet port 36a of secondcoil 28 a, and outlet port 38 of first coil 28 is in fluid communicationwith outlet port 38 a of second coil 28 a. This provides a large flowarea, and hence a high flow rate of cooling fluid through first coil 28and second coil 28 a, allowing a high heat transfer rate with arelatively small and inexpensive first coil 28 and second coil 28 a.

[0028]FIG. 4 is a schematic diagram of a cooling circuit 42 b for usewith a cooling apparatus of a work vehicle, the work vehicle furthercomprising a second axle assembly generally similar to first axleassembly 14 described above. The cooling apparatus is similar to thecooling apparatus described above with reference to FIG. 3. In thisembodiment, second coil 28 a is fluidly disposed in series flowrelationship to first coil 28 by use of a connector, shown as acrossover conduit 56. Outlet port 38 of first coil 28 delivers coolingfluid 40 to inlet port 36 a of second coil 28. This configurationprovides a greater length of time for any given particle of coolingfluid 40 to absorb heat from coils 28 and 28 a at a relatively low flowrate, providing a relatively large efficiency of cooling in terms of thequantity of thermal units transferred per unit of cooling fluid volume.

[0029] In any embodiment of axle assembly 14, first axle shaft 22 and asecond axle shaft may be connected to opposite sides of a differentialgearset 58 (shown in FIG. 1). Generally, a differential housing 60,configured to include a chamber 62 to accommodate differential gearset58, is then provided to support and shield differential gearset 58 andto contain a lubricant for differential gearset 58. Typically, thislubricant will be similar to lubricating fluid 30, and one common bathof lubricating fluid 30 may be used for lubrication of differentialgearset 58 as well as for lubrication and cooling of other parts of axleassembly 14. Crossover conduit 56 may then be given the bowed shapeshown in FIG. 1 in order to not interfere with differential gearset 58.

[0030] It will be understood that the foregoing description is ofexemplary embodiments of the invention, and that the invention is notlimited to the specific forms shown. Other modifications may be made inthe design and arrangement of other elements without departing from thescope and spirit of the invention as expressed in the appended claims.

What is claimed is:
 1. A work vehicle comprising: a frame; an axleassembly coupled to the frame and including a first axle shaft and afirst axle housing, wherein the first axle shaft is disposedsubstantially within the first axle housing; a first wheel coupled tothe axle assembly; an axle lubricating fluid disposed within the firstaxle housing; and a first axle cooling device disposed within the firstaxle housing, in contact with at least a portion of the lubricatingfluid, including a first coil.
 2. The work vehicle of claim 1, furthercomprising a cooling fluid contained within the first coil, wherein thefirst coil is configured to conduct cooling fluid therethrough and tomaintain the cooling fluid separate from the lubricating fluid.
 3. Thework vehicle of claim 2, further comprising a cooling fluid circuitfluidly coupled to the first coil, wherein the cooling circuit includesa cooling fluid pump and a cooling fluid reservoir, and wherein thefirst coil receives cooling fluid from the pump and delivers coolingfluid to the reservoir.
 4. The work vehicle of claim 3, furthercomprising a heat exchanger disposed in the cooling circuit between thefirst coil and the reservoir to remove heat from the cooling fluid. 5.The work vehicle of claim 4, further comprising a control valve disposedto direct at least a portion of the cooling fluid to the first coil at apredetermined pressure difference across the first coil.
 6. The workvehicle of claim 3, further comprising a second wheel, wherein the axleassembly is further coupled to the second wheel and further includes asecond axle shaft, a second axle housing, and a second coil, and furtherwherein the second axle shaft and the second coil are disposedsubstantially within the second axle housing.
 7. The work vehicle ofclaim 6, wherein an inlet of the second coil is in fluid communicationwith an inlet of the first coil and an outlet of the second coil is influid communication with an outlet of the first coil, and parallel flowpaths are thereby provided through the first and second coils.
 8. Thework vehicle of claim 6, wherein: the cooling circuit further includes acrossover conduit; an inlet of the first coil receives cooling fluidfrom the pump; an outlet of the first coil delivers cooling fluidthrough the crossover conduit to an inlet of the second coil; and anoutlet of the second coil delivers cooling fluid to the reservoir, thesecond coil being thereby coupled to the first coil in series flowrelationship by the crossover conduit.
 9. An axle assembly for a workvehicle, the axle assembly comprising: a first axle shaft and a firstaxle housing, wherein the first axle shaft is disposed substantiallywithin the first axle housing; a second axle shaft and a second axlehousing, wherein the second axle shaft is disposed within the secondaxle housing, and wherein the second axle shaft and the second axlehousing are disposed coaxial with, and in opposing relationship to, thefirst axle shaft and the first axle housing, respectively; a firstcooling device disposed within the first axle housing; a second coolingdevice disposed within the second axle housing; a differential gearsethousing positioned intermediate the first and second axle housings anddefining a chamber configured therein to receive a differential gearset;a differential gearset disposed within the chamber and rotativelycoupled to the first and second axle shafts; a lubricating fluiddisposed within the first and second axle housings; and a first axlecooling device disposed within the first axle housing, and a second axlecooling device disposed within the second axle housing.
 10. The axleassembly of claim 9, further comprising a cooling fluid housed withinthe first and second axle cooling devices, wherein the first and secondaxle cooling devices are configured to conduct cooling fluidtherethrough and to maintain the cooling fluid separate from thelubricating fluid.
 11. The axle assembly of claim 10, wherein the firstand second cooling devices include first and second coils, respectively,each coil configured to provide at least two passes of the cooling fluidthrough the lubricating fluid within each of the first and second axlehousings.
 12. The axle assembly of claim 11, wherein the work vehiclefurther includes a cooling fluid circuit for causing cooling fluid toflow through the first and second coils.
 13. The axle assembly of claim12, wherein the cooling circuit includes a cooling fluid pump and acooling fluid reservoir and the first and second coils receive coolingfluid flowing from the pump and deliver it to the reservoir.
 14. Theaxle assembly of claim 13, wherein the cooling circuit further includesa heat exchanger in fluid communication with the first and second coils.15. The axle assembly of claim 13, wherein the cooling circuit furtherincludes a control valve for directing at least a portion of the coolingfluid flow to the first and second coils at a predetermined pressuredifference across the first and second coils.
 16. The axle assembly ofclaim 15, wherein the control valve is configured as a back pressureregulating valve.
 17. The axle assembly of claim 12, further comprisinga crossover conduit for coupling an outlet of the first coil to an inletof the second coil.
 18. A method of cooling an axle assembly of a workvehicle, wherein the axle assembly includes an axle shaft, an axlehousing configured to substantially surround the axle shaft, a coolingcoil housed within the axle housing and having a passage therethroughand outer and inner surfaces, a lubricating fluid disposed within theaxle housing, and a cooling fluid disposed within the passage, andfurther wherein the lubricating fluid is of a higher temperature than isthe outer surface of the coil and the outer surface of the coil is of ahigher temperature than is the cooling fluid, the method comprisingsteps of: removing heat from the lubricating fluid by placing thelubricating fluid in contact with the outer surface of the coil; andremoving the heat from the inner surface of the coil by circulating thecooling fluid through the passage.
 19. The method of claim 18, furthercomprising the step of: directing flow of cooling fluid to the coil byusing a back pressure regulating valve to impose a pressure differenceacross the coil.
 20. The method of claim 19, further comprising the stepof: removing the heat from the cooling fluid by circulating the coolingfluid through a heat exchanger.